LPT-2011-05 BibTeX
@ARTICLE{LPT-2011-05,
AUTHOR = {T. Quaiser and Anna Dittrich and Fred Schaper and M. M\"{o}nnigmann},
TITLE = {{A simple work flow for biologically inspired model reduction - application to early JAK-STAT signaling}},
JOURNAL = {BMC Systems Biology},
YEAR = {2011},
volume = {},
number = {},
pages = {5:30},
month = {},
note = {},
abstract = {Background: Modeling of biological pathways is a key issue in systems biology. When constructing a model, it is
tempting to incorporate all known interactions of pathway species, which results in models with a large number
of unknown parameters. Fortunately, unknown parameters need not necessarily be measured directly, but some
parameter values can be estimated indirectly by fitting the model to experimental data. However, parameter
fitting, or, more precisely, maximum likelihood parameter estimation, only provides valid results, if the
complexity of the model is in balance with the amount and quality of the experimental data. If this is the case
the model is said to be identifiable for the given data. If a model turns out to be unidentifiable, two steps can
be taken. Either additional experiments need to be conducted, or the model has to be simplified.
Results: We propose a systematic procedure for model simplification, which consists of the following steps:
estimate the parameters of the model, create an identifiability ranking for the estimated parameters, and
simplify the model based on the identifiability analysis results. These steps need to be applied iteratively until
the resulting model is identifiable, or equivalently, until parameter variances are small. We choose parameter
variances as stopping criterion, since they are concise and easy to interpret. For both, the parameter estimation
and the calculation of parameter variances, multi-start parameter estimations are run on a parallel cluster. In
contrast to related work in systems biology, we do not suggest simplifying a model by fixing some of its parameters, but change the structure of the model.
Conclusions: We apply the proposed approach to a model of early signaling events in the JAK-STAT pathway.
The resulting model is not only identifiable with small parameter variances, but also shows the best trade-off
between goodness of fit and model complexity.
Online available},
keywords = {},
}
Tom Quaiser, Anna Dittrich, Fred Schaper, Martin Mönnigmann:
A simple work flow for biologically inspired model reduction - application to early JAK-STAT signaling
BMC Systems Biology, 2011, 5:30
Abstract:
Background: Modeling of biological pathways is a key issue in systems biology. When constructing a model, it is
tempting to incorporate all known interactions of pathway species, which results in models with a large number
of unknown parameters. Fortunately, unknown parameters need not necessarily be measured directly, but some
parameter values can be estimated indirectly by fitting the model to experimental data. However, parameter
fitting, or, more precisely, maximum likelihood parameter estimation, only provides valid results, if the
complexity of the model is in balance with the amount and quality of the experimental data. If this is the case
the model is said to be identifiable for the given data. If a model turns out to be unidentifiable, two steps can
be taken. Either additional experiments need to be conducted, or the model has to be simplified.
Results: We propose a systematic procedure for model simplification, which consists of the following steps:
estimate the parameters of the model, create an identifiability ranking for the estimated parameters, and
simplify the model based on the identifiability analysis results. These steps need to be applied iteratively until
the resulting model is identifiable, or equivalently, until parameter variances are small. We choose parameter
variances as stopping criterion, since they are concise and easy to interpret. For both, the parameter estimation
and the calculation of parameter variances, multi-start parameter estimations are run on a parallel cluster. In
contrast to related work in systems biology, we do not suggest simplifying a model by fixing some of its parameters, but change the structure of the model.
Conclusions: We apply the proposed approach to a model of early signaling events in the JAK-STAT pathway.
The resulting model is not only identifiable with small parameter variances, but also shows the best trade-off
between goodness of fit and model complexity.
Online available